A variable-gain amplifier circuit includes an input port, an output port, and first and second amplifiers coupled therebetween. The first amplifier includes a first amplifier path having a first amplification factor, effective when the input signal has a voltage level in a first range, and a second amplifier path having a second amplification factor greater than the first amplification factor, effective when the input signal has a voltage level in a second range including voltages of a first polarity greater than that in the first range. The second amplifier includes a third amplifier path having the first amplification factor, effective when the input signal has a voltage level in a third range, and a fourth amplifier path having the second amplification factor, effective when the input signal has a voltage level in a fourth range including voltages of a second polarity greater than that in the third range.
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31. An apparatus for amplifying an input signal with a variable gain, said apparatus comprising:
means for receiving an input signal; first means for amplifying said input signal by a first amplification factor, when said input signal has a voltage level in a first voltage range; second means for amplifying said input signal by a second amplification factor greater than said first amplification factor, when said input signal has a voltage level in a second voltage range, said second voltage range including voltages of a first polarity greater than that in said first voltage range; third means for amplifying said input signal by said first amplification factor, when said input signal has a voltage level in a third voltage range; and fourth means for amplifying said input signal by said second amplification factor, when said input signal has a voltage level in a fourth voltage range, said fourth voltage range including voltages of a second polarity greater than that in said third voltage range.
17. A method for amplifying an input signal with a variable gain, said method comprising:
receiving an input signal; amplifying said input signal via a first amplifier path having a first amplification factor, when said input signal has a voltage level in a first voltage range; amplifying said input signal via a second amplifier path having a second amplification factor greater than said first amplification factor, when said input signal has a voltage level in a second voltage range, said second voltage range including voltages of a first polarity greater than that in said first voltage range; amplifying said input signal via a third amplifier path having said first amplification factor, when said input signal has a voltage level in a third voltage range; and amplifying said input signal via a fourth amplifier path having said second amplification factor, when said input signal has a voltage level in a fourth voltage range, said fourth voltage range including voltages of a second polarity greater than that in said third voltage range.
1. An amplifier circuit having a variable output gain, said amplifier circuit comprising:
an input port for receiving an input signal; an output port for supplying an output signal; a first amplifier coupled between said input port and said output port, said first amplifier including: a first amplifier path having a first amplification factor, effective when said input signal has a voltage level in-a first voltage range; and a second amplifier path having a second amplification factor greater than said first amplification factor, effective when said input signal has a voltage level in a second voltage range, said second voltage range including voltages of a first polarity greater than that in said first voltage range; and a second amplifier coupled between said input port and said output port, said second amplifier including: a third amplifier path having said first amplification factor, effective when said input signal has a voltage level in a third voltage range; and a fourth amplifier path having said second amplification factor, effective when said input signal has a voltage level in a fourth voltage range, said fourth voltage range including voltages of a second polarity greater than that in said third voltage range. 9. An amplifier circuit having a variable output gain, comprising:
an input port for receiving an input signal; an output port for supplying an output signal; a first amplifier coupled between said input port and said output port, said first amplifier including: a first amplifier path having a first amplification factor; a second amplifier path having a second amplification factor greater than said first amplification factor; and a first selection device coupled with said first amplifier path and said second amplifier path, for activating said first amplifier path when said input signal has a voltage level in a first voltage range, and for activating said second amplifier path when said input signal has a voltage level in a second voltage range, said second voltage range including voltages of a first polarity greater than that in said first voltage range; and a second amplifier coupled between said input port and said output port, said second amplifier including: a third amplifier path having said first amplification factor; a fourth amplifier path having said second amplification factor; and a second selection device coupled with said third amplifier path and said fourth amplifier path, for activating said third amplifier path when said input signal has a voltage level in a third voltage range, and for activating said fourth amplifier path when said input signal has a voltage level in a fourth voltage range, said fourth voltage range including voltages of a second polarity greater than that in said third voltage range. 24. A method for amplifying an input signal with a variable gain, said input signal being input via an input port and an amplified signal being output via an output port, said method comprising:
providing a first amplifier path between said input port and said output port, said first amplifier path having a first amplification factor; providing a second amplifier path between said input port and said output port, said second amplifier path having a second amplification factor greater than said first amplification factor; providing a third amplifier path between said input port and said output port, said third amplifier path having said first amplification factor; providing a fourth amplifier path between said input port and said output port, said fourth amplification path having said second amplification factor; receiving an input signal; detecting a voltage level of said input signal; activating said first amplifier path when said input signal has a voltage level in a first voltage range; activating said second amplifier path when said input signal has a voltage level in a second voltage range, said second voltage range including voltages of a first polarity greater than that in said first voltage range; activating said third amplifier path when said input signal has a voltage level in a third voltage range; activating said fourth amplifier path when said input signal has a voltage level in a fourth voltage range, said fourth voltage range including voltages of a second polarity greater than that in said third voltage range; and amplifying said input signal via activated amplifier paths.
36. An apparatus for amplifying an input signal with a variable gain, said apparatus comprising:
means for receiving an input signal; means for outputting an amplified signal; means for providing a first amplifier path between said means for receiving and said means for outputting, said first amplifier path having a first amplification factor; means for providing a second amplifier path between said means for receiving and said means for outputting, said second amplifier path having a second amplification factor greater than said first amplification factor; means for providing a third amplifier path between said means for receiving and said means for outputting, said third amplifier path having said first amplification factor; means for providing a fourth amplifier path between said means for receiving and said means for outputting, said fourth amplification path having said second amplification factor; means for detecting a voltage level of said input signal; means for activating said first amplifier path when said input signal has a voltage level in a first voltage range; means for activating said second amplifier path when said input signal has a voltage level in a second voltage range, said second voltage range including voltages of a first polarity greater than that in said first voltage range; means for activating said third amplifier path when said input signal has a voltage level in a third voltage range; and means for activating said fourth amplifier path when said input signal has a voltage level in a fourth voltage range, said fourth voltage range voltages of a second polarity greater than that in said third voltage range.
2. An amplifier circuit according to
said first voltage range includes voltages of the first polarity equal to or smaller than a first voltage value, said second voltage range includes voltages of the first polarity equal to or greater than said first voltage value, said third voltage range includes voltages of the second polarity equal to or smaller than a second voltage value, and said fourth voltage range includes voltages of the second polarity equal to or greater than said second voltage value.
3. An amplifier circuit according to
4. An amplifier circuit according to
5. An amplifier circuit according to
6. An amplifier circuit according to
7. An amplifier circuit according to
8. An amplifier circuit according to
10. An amplifier circuit according to
said first voltage range includes voltages of the first polarity equal to or smaller than a first voltage value, said second voltage range includes voltages of the first polarity equal to or greater than said first voltage value, said third voltage range includes voltages of the second polarity equal to or smaller than a second voltage value, and said fourth voltage range includes voltages of the second polarity equal to or greater than said second voltage value.
11. An amplifier circuit according to
12. An amplifier circuit according to
13. An amplifier circuit according to
14. An amplifier circuit according to
15. An amplifier circuit according to
16. An amplifier circuit according to
18. A method according to
said first voltage range includes voltages of the first polarity equal to or smaller than a first voltage value, said second voltage range includes voltages of the first polarity equal to or greater than said first voltage value, said third voltage range includes voltages of the second polarity equal to or smaller than a second voltage value, and said fourth voltage range includes voltages of the second polarity equal to or greater than said second voltage value.
19. A method according to
22. A method according to
23. A method according to
25. A method according to
said first voltage range includes voltages of the first polarity equal to or smaller than a first voltage value, said second voltage range includes voltages of the first polarity equal to or greater than said first voltage value, said third voltage range includes voltages of the second polarity equal to or smaller than a second voltage value, and said fourth voltage range includes voltages of the second polarity equal to or greater than said second voltage value.
26. An amplifier circuit according to
29. A method according to
30. A method according to
32. An apparatus according to
said first voltage range includes voltages of the first polarity equal to or smaller than a first voltage value, said second voltage range includes voltages of the first polarity equal to or greater than said first voltage value, said third voltage range includes voltages of the second polarity equal to or smaller than a second voltage value, and said fourth voltage range includes voltages of the second polarity equal to or greater than said second voltage value.
33. An apparatus according to
34. An apparatus according to
35. An apparatus according to
37. An apparatus according to
said first voltage range includes voltages of the first polarity equal to or smaller than a first voltage value, said second voltage range includes voltages of the first polarity equal to or greater than said first voltage value, said third voltage range includes voltages of the second polarity equal to or smaller than a second voltage value, and said fourth voltage range includes voltages of the second polarity equal to or greater than said second voltage value.
38. An apparatus according to
39. An apparatus according to
40. An apparatus according to
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The present invention relates to broadband telecommunications. More particularly, the present invention relates to a Class-AB amplifier for a line driver in a broadband telecommunications system.
However, the gain of an error amplifier cannot be made arbitrarily large because of offset of the error amplifier, which largely depends on the matching of transistors in the error amplifier. The offset of the error amplifier is statistical in nature and considered random, and varies over process and temperature. Such a random offset of the error amplifier causes a random variation in an offset voltage. Since a quiescent current variation (ΔIQ/IQ) is proportional to the offset voltage (ΔV) and the gain (Av) of the amplifier, a large gain of the amplifier causes a large quiescent current variation, which results in excess power dissipation and/or degraded linearity of the overall amplifier.
The quiescent current is basically the operating supply current of the amplifiers, and is required to bias the internal circuitry (such as output devices) of the amplifiers. Since the quiescent current must be always be supplied whether there is signal applied or not, it adds to the power consumption and power dissipation of the amplifier. Designing for very low quiescent current significantly reduces the power dissipation. However, on the other hand, in order to obtain a low distortion and/or high linearity performance of the amplifier, an additional biasing current (i.e., a larger quiescent current) is typically required for the internal circuitry. In such a case, a large fluctuation in the quiescent current also degrades the linearity of the amplifier.
There are two conventional approaches to solve the offset problem of the error amplifier. A widely adopted approach is to limit the gain of the error amplifier (typically an amplification factor of less than 10) to reduce the quiescent current variation due to a random offset. This approach is effective when the signal bandwidth is low and/or the required linearity level of the amplifier is not high. However, simply limiting the error amplifier gain is not an acceptable solution in the applications where the bandwidth and linearity requirements are more demanding, for example, in broadband communications. In broadband communications, the linearity or signal to noise ratio (SNR) of the amplifier dictates the achievable data rate between a transmitter and a receiver.
The other approach to solve the offset problem of the error amplifier is to monitor the quiescent current of the amplifier and adjust the offset using a quiescent control circuit in negative feedback configuration. This approach has been used in Integrated Services Digital Network (ISDN) applications with moderate linearity level. However, complex hardware is required to realize the quiescent current control circuit.
Accordingly, it would be desirable to reduce the quiescent current variation due to amplifier offset while maintaining a sufficient bandwidth and good linearity of the overall amplifier without adding a complex control circuit.
An amplifier circuit having a variable output gain includes an input port for receiving an input signal, an output port for supplying an output signal, a first amplifier coupled between the input port and the output port, and a second amplifier coupled between the input port and the output port. The first amplifier includes a first amplifier path having a first amplification factor, effective when the input signal has a voltage level in a first voltage range, and a second amplifier path having a second amplification factor greater than the first amplification factor, effective when the input signal has a voltage level in a second voltage range, the second voltage range including voltages of a first polarity greater than that in the first voltage range. The second amplifier includes a third amplifier path having the first amplification factor, effective when the input signal has a voltage level in a third voltage range, and a fourth amplifier path having the second amplification factor, effective when the input signal has a voltage level in a fourth voltage range, the fourth voltage range including voltages of a second polarity greater than that in the third voltage range.
The accompanying drawings, which are incorporated into and constitute a part of this specification, illustrate one or more embodiments of the present invention and, together with the detailed description, serve to explain the principles and implementations of the invention.
In the drawings:
Embodiments of the present invention are described herein in the context of an amplifier circuit for a line driver. Those of ordinary skill in the art will realize that the following detailed description of the present invention is illustrative only and is not intended to be in any way limiting. Other embodiments of the present invention will readily suggest themselves to such skilled persons having the benefit of this disclosure. Reference will now be made in detail to implementations of the present invention as illustrated in the accompanying drawings. The same reference indicators will be used throughout the drawings and the following detailed description to refer to the same or like parts.
In the interest of clarity, not all of the routine features of the implementations described herein are shown and described. It will, of course, be appreciated that in the development of any such actual implementation, numerous implementation-specific decisions must be made in order to achieve the developer's specific goals, such as compliance with application- and business-related constraints, and that these specific goals will vary from one implementation to another and from one developer to another. Moreover, it will be appreciated that such a development effort might be complex and time-consuming, but would nevertheless be a routine undertaking of engineering for those of ordinary skill in the art having the benefit of this disclosure.
Because of a push-pull nature of the Class-AB amplifier structure, both N-type and P-type error amplifiers are required. The first amplifier 26 may be a P-type error amplifier, and the second amplifier 28 may be an N-type error amplifier. It should be noted that
As shown in
As shown in
As shown in
The gate of the first NMOS 51 is coupled to the first input terminal 42a, the source of the first NMOS 51 is coupled to the second supply voltage (VGND), and the drain of the first NMOS 51 is coupled to the first node 46. The gate of the second NMOS 52 is coupled to the second input terminal 42b, the source of the second NMOS 52 is coupled to the second supply voltage (VGND), and the drain of the second NMOS 52 is coupled via the second node 48 to the output terminal 44.
The gate and drain of the first PMOS 53 are coupled to the first node 46, and the source of the first PMOS 53 is coupled to the first supply voltage (VDD). The gate of the second PMOS 54 is coupled to the first node 46, the source of the second PMOS 54 is coupled to the first supply voltage (VDD), and the drain of the second PMOS 54 is coupled via the second node 48 to the output terminal 44. The gate of the third PMOS 55 is couple to the first node 46, the source of the third PMOS 55 is coupled to the first supply voltage (VDD), and the drain of the third PMOS 55 is coupled to the third node 49. The gate of the fourth PMOS 56 is coupled to the first node 46, the source of the fourth PMOS 56 is coupled to the first supply voltage (VDD), and the drain of the fourth PMOS 56 coupled to the output terminal 44.
The gate of the third NMOS 57 is coupled to a balance voltage (Vb), which approximates the input voltage Vinp, the drain of the third NMOS 57 is coupled to the third node 49, and the source of the third NMOS 57 is coupled to the second supply voltage (VGND). The gate and drain of the fourth NMOS 58 are coupled to the output terminal 44, and the source of the fourth NMOS 58 is coupled to the second supply voltage (VGND).
The operation of the amplifier circuit 50 is described referring to its P-type structure shown in FIG. 3A. When there is no input signal, the amplifier circuit 50 balances itself and the current from the first supply voltage (VDD) to the second supply voltage (VGND) is equally split. Thus a voltage V1 at the first node 46, a voltage V2 at the second node 48, a voltage V3 at the third node 49, and an output voltage Vout are the same. The voltage V3 at the third node 49 is in an equilibrium state and the transistor M7 (NMOS 57) is in saturation.
When the input signal (Vinm-Vinp) is small, the amplifier circuit 50 also balances itself in accordance with the small signal model. That is, the current from the first supply voltage (VDD) to the second supply voltage (VGND) is still equally split, and thus a voltage V1 at the first node 46, a voltage V2 at the second node 48, a voltage V3 at the third node 49, and an output voltage Vout should be the same. Thus, the voltage V3 at the third node 49 becomes close to its equilibrium and the transistor M7 (NMOS 57) is forced to be in saturation. Therefore, effectively, the two transistors M7 (NMOS 57) and M8 (NMOS 58) are coupled in series to the output terminal 44, forming a low-gain amplifier path 60, as shown in FIG. 4A. The output impedance is low because gm7 and gm8 are in series.
It should be noted that in the amplifier path, a gain contribution from the conductance gds5 of the transistor M5 (PMOS 55) and a gain contribution from the conductance gds7 of the transistor M7 (PMOS 57) can be neglected compared with that from the transconductances gm7 and gm8 of the transistors M7 and M8, since the transconductance of a transistor is typically significantly greater than the conductance (for example, by a factor about 10 or more).
Accordingly, the amplification factor (gain) AV1 is substantially determined by transconductances of the transistors M8 and M7 coupled in series to the output port, and is approximated as:
where gm1 is a transconductance of the transistor M1(NMOS 51), gm8 is a transconductance of the transistor M7 (NMOS 57), and gm8 is a transconductance of the transistor M8 (NMOS 58). It should be noted that the transconductance gm of a transistor in saturation is significantly greater than its drain-source conductance gds, and thus the resistance of the transistor is approximated by 1/gm. By choosing an appropriate device ratio of the transistors, the amplification factor for a small signal may be set to be about 10 or less. This makes the error amplifier gain small when the input signal is small, reducing the quiescent current variation due to offset of the amplifier.
When the input signal (Vinm-Vinp) is large, on the other hand, the transistor M5 (PMOS 55) is in strong inversion, and the transistor M7 (NMOS 57) is pushed into a triode region and operates as a switch. That is, referring back to
Accordingly, the amplifier factor AV2 is substantially determined by these drain-source conductances coupled in parallel, and given as:
where gds2, gds4, and gds6 are the drain-source conductances of the transistors M2, M4, and M6, respectively, and
By choosing an appropriate device ratio for the transistors, the amplification factor for a large signal may be set to be about 100 or more. This makes the error amplifier gain high when the input signal is large, providing effective amplification.
Although the detailed structure and operation of the amplifier circuit 50 have been described referring to the P-type structure shown in
When the input signal has the negative polarity and a voltage smaller than a certain value Vm, the low-gain amplifier path 60 (
Similarly, when the input signal has the positive polarity and a voltage smaller than a certain value Vp, the low-gain amplifier path in the N-type amplifier structure is in effect and the input signal is amplified with a low gain. The value Vp is determined by the device ratio of the transistors. The value Vp-Vref may be equal to the value Vref-Vm to make the P-type and N-type structures symmetric. As is understood from the N-type error amplifier structure (FIG. 3B), the low-gain amplifier path remains effective for an input signal having a voltage below the reference level Vref, i.e., the input signal having the negative polarity. Accordingly, the N-type low-gain amplifier path is effective for an input signal of a third range 76, as shown in FIG. 5. On the other hand, when the input signal has the positive polarity and a voltage greater than the value Vp, the high-gain amplifier in the N-type amplifier structure is in effect and the input signal is amplified with a high gain. That is, the N-type high-gain amplifier path is effective for an input signal of a fourth range 78, as indicated in FIG. 5.
Accordingly, a large input signal with a negative polarity is effectively amplified with a high-gain path of the P-type amplifier structure, while the N-type amplifier structure remains with a low output gain. When an input signal is large and has the positive polarity, the input signal is effectively amplified via a high-gain path of the N-type amplifier structure, while the P-type amplifier structure remains with a low output gain. Thus, a large input signal of either polarity is amplified with a high gain, achieving a good linearity of the overall amplifier. In case of a small input signal of either negative or positive polarity, the low-gain amplifier path is effective in the both P-type and N-type amplifier structures, and thus the output gain is low, reducing the quiescent current variation due to the offset of the error amplifiers.
As is understood from the circuit operation described above, the transition from the low-gain amplifier path to the high-gain amplifier path is gradual, and depends only on the device ratio. There is no external signal detector circuitry, and the signal level detector with a switching feature is implemented in the error amplifier structure itself. Referring back to
While embodiments and applications of this invention have been shown and described, it would be apparent to those skilled in the art having the benefit of this disclosure that many more modifications than mentioned above are possible without departing from the inventive concepts herein. The invention, therefore, is not to be restricted except in the spirit of the appended claims.
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